JP6782136B2 - Spacer and battery pack - Google Patents

Description

The present invention relates to spacers and assembled batteries.

Conventionally, there is an assembled battery that is mounted on a vehicle such as an electric vehicle and used as a power source for driving a vehicle motor. The assembled battery (battery module as one form) is configured by laminating cell cells (flat batteries) using spacers (insulating plates) (see Patent Document 1).

JP-A-2009-231267

In an assembled battery, for example, water droplets or a water film generated by dew condensation may collect in a gap between a cell and a spacer. Water droplets and water films cause electrical short circuits between the members constituting the assembled battery and cause electric leakage.

An object of the present invention is to provide a spacer and an assembled battery capable of suppressing electric leakage due to dew condensation.

The spacer for achieving the above object is used for a cell cell provided with a battery body including a power generation element and formed flat, and an electrode tab derived from the battery body. The spacer has a protrusion, a recess, and an opening. The protrusion is formed in a convex shape and is inserted into a hole or notch provided in the electrode tab to guide the electrode tab. The recess is formed in a concave shape and is separated from the electrode tab around the root of the protrusion. The opening allows a part of the recess to communicate with the side surface side.

The assembled battery for achieving the above object includes a cell battery, a spacer, and a bus bar. The unit cell includes a battery body including a power generation element and formed flat, and an electrode tab derived from the battery body. The spacer has a convexly formed protrusion that is inserted into a hole or notch provided in the electrode tab to guide the electrode tab, and a concave portion that is separated from the electrode tab around the root of the protrusion. It is provided with a recess formed in the above and an opening for communicating a part of the recess to the side surface side. The bus bar electrically connects the electrode tabs of the different cells.

According to such a spacer and an assembled battery, it is possible to suppress electric leakage due to dew condensation.

It is a perspective view which shows the assembled battery which concerns on embodiment. A state in which the pressurizing unit (upper pressurizing plate, lower pressurizing plate and left and right side plates) is removed from the assembled battery shown in FIG. 1, and a part of the bus bar unit (protective cover, anode side terminal and cathode side terminal) is removed. It is a perspective view which shows. It is a perspective view which shows the main part in the state which the bus bar is joined to the electrode tab of a laminated cell, by the cross section. FIG. 3A is an end view showing FIG. 3A from the side. It is a perspective view which shows the state which the bus bar holder and the bus bar are removed from the laminated body shown in FIG. It is a perspective view which shows the state which the 1st cell subassi and the 2nd cell subassi shown in FIG. 4 are electrically connected by a bus bar. A state in which the first cell subassi (three sets of cells connected in parallel) shown in FIG. 4 is disassembled for each cell, and the first spacer and the second spacer are removed from one (top) cell. It is a perspective view which shows. It is a perspective view which shows a part of a cell and a part of a 1st spacer. It is a side view which shows the cell and the 1st spacer of FIG. It is a perspective view which shows the 1st spacer of FIG. It is a top view which shows the 1st spacer of FIG. It is a side view which shows which the base end part of the electrode tab is schematically added to the 1st spacer of FIG. It is a side view which shows the 1st spacer of FIG.

Hereinafter, embodiments of the present invention will be described with reference to the attached drawings. In the drawings, the same members are designated by the same reference numerals, and duplicate description will be omitted. In the drawings, the size and ratio of each member may be exaggerated to facilitate understanding of the embodiment and may differ from the actual size and ratio.

In each figure, the arrows represented by X, Y, and Z are used to indicate the orientation of the assembled battery 100. The direction of the arrow represented by X indicates the longitudinal direction of the assembled battery 100. The direction of the arrow represented by Y indicates the lateral direction of the assembled battery 100. The direction of the arrow represented by Z indicates the stacking direction of the assembled battery 100.

FIG. 1 is a perspective view showing the assembled battery 100 according to the embodiment. In FIG. 2, the pressurizing unit 120 (upper pressurizing plate 121, lower pressurizing plate 122, and left and right side plates 123) is removed from the assembled battery 100 shown in FIG. 1, and a part of the bus bar unit 130 (protective cover 135 and anode). It is a perspective view which shows the state which the side terminal 133 and the cathode side terminal 134) were removed. FIG. 3A is a perspective view showing a main part in a state where the bus bar 132 is joined to the electrode tab 112 of the laminated cell 110 by a cross section. FIG. 3B is an end view showing FIG. 3A from the side. FIG. 4 is a perspective view showing a state in which the bus bar holder 131 and the bus bar 132 are removed from the laminated body 110S shown in FIG. FIG. 5 is a perspective view showing a state in which the first cell subassi 110M and the second cell subassi 110N shown in FIG. 4 are electrically connected by a bus bar 132. FIG. 6 shows that the first cell subassi 110M (three sets of single batteries 110 connected in parallel) shown in FIG. 4 is disassembled for each single battery 110, and one of them (top) from the single battery 110 to the first spacer. It is a perspective view which shows the state which 114 and the 2nd spacer 115 were removed. FIG. 7 is a perspective view showing a part of the cell 110 and a part of the first spacer 114. FIG. 8 is a side view showing the cell 110 and the first spacer 114 of FIG. FIG. 9 is a perspective view showing the first spacer 114 of FIG. 7. FIG. 10 is a top view showing the first spacer 114 of FIG. 7. FIG. 11 is a side view showing a base end portion 112c of the electrode tab 112 schematically added to the first spacer 114 of FIG. 7. FIG. 12 is a side view showing the first spacer 114 of FIG. 7.

With reference to FIGS. 3B, 7 and 12, the spacer (first spacer 114) according to the embodiment is derived from the battery body 110H and the battery body 110H, which are formed flat including the power generation element 111, to be outlined. It is used for the cell 110 provided with the electrode tab 112 (anode side electrode tab 112A and cathode side electrode tab 112K). The first spacer 114 has a protrusion (boss 114r), a recess (first recess 114s), and an opening (first opening 114v). The boss 114r is formed in a convex shape and is inserted into a hole 112e or a notch provided in the electrode tab 112 to guide the electrode tab 112. The first recess 114s is formed in a concave shape and is separated from the electrode tab 112 around the root of the boss 114r. The first opening 114v communicates a part of the first recess 114s to the side surface side.

With reference to FIGS. 3B, 7 and 12, the assembled battery 100 according to the embodiment includes, by outline, a cell 110, a spacer (first spacer 114), and a bus bar 132. The cell 110 includes a flat battery body 110H including a power generation element 111, and an electrode tab 112 (anode side electrode tab 112A and cathode side electrode tab 112K) derived from the battery body 110H. The first spacer 114 has a convex protrusion (boss 114r) formed in a hole 112e provided in the electrode tab 112 or a notch to guide the electrode tab 112, and the electrode tab 112 around the base of the boss 114r. It is provided with a recess (first recess 114s) formed in a concave shape so as to be separated from the surface, and an opening (first opening 114v) for communicating a part of the first recess 114s to the side surface side. The bus bar 132 electrically connects the electrode tabs 112 of different cell units 110 to each other.

A plurality of assembled batteries 100 are mounted on a vehicle such as an electric vehicle and used as a power source for driving a vehicle motor. The assembled battery 100 is configured by electrically connecting a laminated body 110S formed by laminating a plurality of single batteries 110 by a bus bar unit 130 in a state of being pressurized by the pressurizing unit 120. Hereinafter, each configuration of the assembled battery 100 including the spacers (first spacer 114 and second spacer 115) will be described.

The configuration of the laminated body 110S will be described in detail.

As shown in FIG. 4, the laminated body 110S comprises a first cell sub-assess 110M composed of three electrically connected single cells 110 and a second cell sub-asse 110N composed of three electrically connected parallel cells 110. It is configured by alternately connecting in series.

As shown in FIG. 4, the first cell subassi 110M is a three-cell battery 110 located in the first stage (bottom stage), the third stage, the fifth stage, and the seventh stage (top stage) in the assembled battery 100. Corresponds to. As shown in FIG. 4, the second cell subassi 110N corresponds to the three cell batteries 110 located in the second, fourth, and sixth stages of the assembled battery 100.

The first cell subassi 110M and the second cell subassi 110N have the same configuration. However, as shown in FIGS. 4 and 5, the first cell subassi 110M and the second cell subassi 110N have three anode side electrode tabs 112A and three cathode side electrode tabs 112K by exchanging the top and bottom of the three cell cells 110. Are arranged so as to be alternately located along the Z direction.

In the first cell subassi 110M, as shown in FIGS. 4 and 5, all the anode side electrode tabs 112A are located on the right side in the drawing, and all the cathode side electrode tabs 112K are located on the left side in the drawing.

In the second cell subassi 110N, as shown in FIGS. 4 and 5, all the anode side electrode tabs 112A are located on the left side in the drawing, and all the cathode side electrode tabs 112K are located on the right side in the drawing. If the top and bottom of each of the three cells 110 are simply replaced, the orientation of the tip 112d of the electrode tab 112 will vary up and down in the Z direction. Therefore, each tip 112d is refracted downward so that the directions of the tips 112d of the electrode tabs 112 of all the cells 110 are aligned.

The cell 110 corresponds to, for example, a lithium ion secondary battery. A plurality of AA batteries 110 are connected in series in order to satisfy the specifications of the drive voltage of the vehicle motor. A plurality of AA cells 110 are connected in parallel in order to secure the capacity of the batteries and extend the mileage of the vehicle.

As shown in FIGS. 3A and 3B, the cell 110 seals a flat battery body 110H including a power generation element 111 for charging and discharging, an electrode tab 112 for facing the power generation element 111 to the outside, and a power generation element 111. It contains a laminating film 113 to be stopped.

The power generation element 111 charges electric power from an outdoor charging stand or the like and then discharges the electric power to a vehicle motor or the like to supply driving electric power. The power generation element 111 is configured by laminating a plurality of sets of anodes and cathodes separated by a separator.

As shown in FIGS. 3A to 8, the electrode tab 112 faces the power generation element 111 to the outside. The electrode tab 112 is composed of an anode side electrode tab 112A and a cathode side electrode tab 112K. The base end side of the anode side electrode tab 112A is joined to all the anodes included in one power generation element 111. The anode-side electrode tab 112A is formed from a thin plate and is made of aluminum according to the characteristics of the anode. The base end side of the cathode side electrode tab 112K is joined to all the cathodes included in one power generation element 111. The cathode side electrode tab 112K is formed from a thin plate shape and is made of copper according to the characteristics of the cathode.

The electrode tab 112 is formed in an L shape as shown in FIGS. 3B, 7 and 8. The base end portion 112c of the electrode tab 112 is supported by the contact portion (first contact portion 114i and second contact portion 114j) of the first spacer 114. The tip portion 112d of the electrode tab 112 is refracted along the lower side in the Z direction and faces the side surface (contact surface 114h) of the first spacer 114.

The shape of the tip portion 112d of the electrode tab 112 is not limited to the L-shape. For example, the electrode tab 112 may be formed in a U shape by further extending the tip portion 112d and folding back the extending portion toward the power generation element 111. Further, the base end portion 112c of the electrode tab 112 may be formed in a wavy shape or a curved shape. The tip portion 112d of the electrode tab 112 comes into surface contact with the bus bar 132.

As shown in FIGS. 7 and 8, the electrode tab 112 is provided with a hole 112e at a central portion 112f along the width direction. The holes 112e are formed in an elongated shape from the base end portion 112c of the electrode tab 112 to the tip end portion 112d. The hole 112e of the electrode tab 112 is inserted with the boss 114r of the first spacer 114.

As shown in FIGS. 3A and 3B, the laminated film 113 is composed of a pair, and the battery body 110H is sandwiched and sealed from above and below along the Z direction. The pair of laminated films 113 lead the anode side electrode tab 112A and the cathode side electrode tab 112K to the outside from the gap of one end portion 113a along the Y direction. As shown in FIG. 8, the laminated film 113 includes a sheet-shaped metal layer 113M and a sheet-shaped insulating layer 113N that covers and insulates the metal layer 113M from both sides.

The cell 110 is supported by a pair of spacers (first spacer 114 and second spacer 115) as shown in FIG. 6, and as shown in FIGS. 3 (A), 3 (B), and FIG. Stacked.

As shown in FIGS. 2, 3A and 3B, the pair of spacers (first spacer 114 and second spacer 115) arrange the cells 110 at regular intervals along the Z direction. The first spacer 114 supports the cell 110 on the side provided with the electrode tab 112. The second spacer 115 supports the cell 110 on the side not provided with the electrode tab 112 so as to face the first spacer 114 in the X direction of the cell 110.

As shown in FIG. 6, the first spacer 114 is formed of a long plate shape having irregularities and is made of reinforced plastics having insulating properties. The first spacer 114 is provided so as to face the side of one end portion 113a of the pair of laminated films 113. As shown in FIGS. 7 and 8, the first spacer 114 supports one end of the cell 110 by the contact portions (first contact portion 114i and second contact portion 114j).

The first spacer 114 includes a pair of support surfaces 114b along the Y direction. The first spacer 114 is provided with a contact surface 114h on a side surface adjacent to the support surface 114b and along the Z direction. As shown in FIG. 3B, the contact surface 114h is in contact with the tip portion 112d of the electrode tab 112, and the tip portion 112d is positioned along the X direction.

As shown in FIGS. 7 to 9, the first spacer 114 has a convex first contact portion 114i protruding upward in a rectangular shape from the flat support surface 114b in the Z direction to the support surface 114b. A plurality of them are provided along the Y direction of. The first contact portion 114i supports the base end portion 112c of the electrode tab 112 of the cell 110 from below. The first contact portions 114i are provided at the center of the support surface 114b, two separated from each other, and one at both ends of the support surface 114b, for a total of four. The first contact portion 114i supports the central portion 112f, the one end portion 112g, and the other end portion 112h along the width direction of the electrode tab 112.

As shown in FIGS. 7 to 9, the first spacer 114 includes a convex boss 114r at the center of each support surface 114b. The boss 114r is inserted into the hole 112e opened in the central portion 112f of the electrode tab 112 to regulate the position of the electrode tab 112. As shown by the dotted line in FIG. 8, the boss 114r is crimped and fixed to the portion around the hole 112e of the electrode tab 112. The boss 114r is crimped by pressing the boss 114r while heating it to deform it into a hemispherical shape.

As shown in FIGS. 7 and 9, the first spacer 114 includes a first recessed portion 114s in which a support surface 114b located around a base end portion of the boss 114r is annularly recessed around the boss 114r. There is. A part of the first recess 114s faces the contact surface 114h. The first recess 114s faces the electrode tab 112 of the cell 110, but is separated from the electrode tab 112.

As shown in FIGS. 7 to 9, the first spacer 114 includes a convex second contact portion 114j that protrudes in an annular shape from each support surface 114b in the upward direction along the Z direction. The second contact portion 114j partially supports one end portion 113a of the laminated film 113 of the cell 110. The height of the second contact portion 114j is lower than that of each of the first contact portions 114i. The end of the annular second abutment portion 114j is connected to each of the first abutment portions 114i.

As shown in FIGS. 7 to 9, the first spacer 114 includes a second recessed portion 114t in a portion partitioned by the annular second contact portion 114j. The second recess 114t is formed in a concave shape with the support surface 114b as the bottom surface and the second contact portion 114j as the side surface. A part of the second recess 114t faces the contact surface 114h. The second recess 114t faces one end 113a of the laminated film 113 of the cell 110 and the electrode tab 112, but is separated from them.

As shown in FIG. 7, the first spacer 114 is provided with a third recess 114u at a portion partitioned on four sides by an annular second contact portion 114j. The third recess 114u is formed in a concave shape with the support surface 114b as the bottom surface and the second contact portion 114j as the side surface. The third recess 114u faces one end 113a of the laminated film 113 of the cell 110 and the electrode tab 112, but is separated from them.

The gap between the first spacer 114 and the cell 110 from the recess (first recess 114s and second recess 114t) of the first spacer 114 to the side surface (contact surface 114h) functions as a drainage channel. To do. As a result, the assembled battery 100 does not reduce the insulation resistance even if water droplets or a water film are generated due to dew condensation, and prevents the constituent members from being electrically short-circuited or leaking. The depth of the recesses (first recess 114s and second recess 114t) is appropriately determined based on the amount of water generated by dew condensation and the surface tension of water. If an insulating member is provided between the first spacer 114 and the cell 110 to forcibly insulate the battery, the size of the assembled battery 100 will increase and the manufacturing cost will increase.

As shown in FIGS. 6 and 7, the first spacer 114 is provided with a pair of connecting pins 114c protruding upward at both ends of the support surface 114b along the Y direction. The pair of connecting pins 114c have a cylindrical shape, and the cell 110 is positioned by inserting it into the connecting holes 113c opened at both ends of the one end portion 113a of the laminated film 113 along the Y direction.

As shown in FIG. 3B, the plurality of first spacers 114 are in contact with the upper surface 114a of the first spacer 114 and the lower surface 114d of the other first spacer 114. As shown in FIG. 3B, the plurality of first spacers 114 have a cylindrical positioning pin 114e protruding from the upper surface 114a of the first spacer 114 and a positioning pin 114e opened on the lower surface 114d of the other first spacer 114. By fitting the holes 114f, they are positioned with each other.

As shown in FIGS. 7 to 9, the first spacer 114 is a rectangular parallelepiped pressing portion 114k that protrudes downward in the Z direction so as to face the first contact portion 114i along the Z direction. It has. As shown in FIG. 3B, the pressing portion 114k of the other first spacer 114 located relatively upward and the first contact portion 114i of the one first spacer 114 located relatively downward make one. The electrode tab 112 supported by the first spacer 114 is sandwiched and fixed.

As shown in FIGS. 6 and 7, the first spacer 114 is provided with locating holes 114g at both ends along the Y direction. In the locate hole 114g, a bolt that connects the plurality of assembled batteries 100 while positioning them along the Z direction is inserted.

Since it is not necessary to support the electrode tab 112, the second spacer 115 is configured by simplifying the first spacer 114. As shown in FIG. 6, the second spacer 115 has a contact portion (second contact portion) that supports the other end portion 113b of the laminated film 113, and the other end portion of the cell 110, similarly to the first spacer 114. The recesses (second recess and third recess) facing the 113b side, the positioning pin 114e for positioning the second spacers, the connecting pin 115c for positioning the cell 110, and the plurality of assembled batteries 100 are positioned. It is provided with a locate hole of 115 g or the like into which a bolt to be connected is inserted.

The hollow spacer 116 is a so-called collar. The hollow spacer 116 is made of a metal having a cylindrical shape and having sufficient strength. The hollow spacer 116 is inserted into the locating hole 114g of the first spacer 114 and the locating hole 115g of the second spacer 115, respectively. The hollow spacer 116 reinforces the first spacer 114 and the second spacer 115 by externally inserting bolts that connect the plurality of assembled batteries 100 while positioning them.

The configuration of the pressurizing unit 120 will be described in detail.

The pressurizing unit 120 includes an upper pressurizing plate 121 and a lower pressurizing plate 122 that pressurize the power generation element 111 of each cell 110 of the laminated body 110S from above and below, and an upper pressurizing plate 121 and a lower portion in a state where the laminated body 110S is pressurized. It includes a pair of side plates 123 for fixing the pressure plate 122.

As shown in FIGS. 1 and 2, the upper pressurizing plate 121, together with the lower pressurizing plate 122, sandwiches and holds a plurality of cell cells 110 constituting the laminated body 110S from above and below, and holds the power generation element of each cell 110. It pressurizes 111. The upper pressure plate 121 is made of a metal having a plate shape having irregularities and having sufficient rigidity. The upper pressure plate 121 is provided on a horizontal surface. As shown in FIG. 2, the upper pressurizing plate 121 includes a pressurizing surface 121a that pressurizes the power generation element 111 downward. The pressure surface 121a is formed flat and protrudes downward from the central portion of the upper pressure plate 121. The upper pressure plate 121 is provided with a locate hole 121b into which a bolt for connecting the assembled batteries 100 is inserted. The locate holes 121b are through holes and are open at the four corners of the upper pressure plate 121.

As shown in FIG. 2, the lower pressure plate 122 has the same shape as the upper pressure plate 121, and is provided so as to reverse the top and bottom of the upper pressure plate 121. Similar to the upper pressurizing plate 121, the lower pressurizing plate 122 has a pressurizing surface 122a that pressurizes the power generation element 111 upward, and a locate hole for inserting a bolt that connects the assembled batteries 100 to each other while positioning them in the Z direction. It is equipped with 122b.

As shown in FIGS. 1 and 2, the pair of side plates 123 fix the upper pressure plate 121 and the lower pressure plate 122 in a state where the laminated body 110S is pressurized. That is, the pair of side plates 123 keeps the distance between the upper pressure plate 121 and the lower pressure plate 122 constant. Further, the pair of side plates 123 cover and protect the side surfaces of the stacked single batteries 110 along the X direction. The side plate 123 is formed in a flat plate shape and is made of metal. The pair of side plates 123 are provided upright so as to face both side surfaces of the stacked single batteries 110 along the X direction. The pair of side plates 123 are welded to the upper pressure plate 121 and the lower pressure plate 122.

The configuration of the bus bar unit 130 will be described in detail.

The bus bar unit 130 includes a bus bar holder 131 that integrally holds a plurality of bus bars 132, a bus bar 132 that electrically connects the electrode tabs 112 of the vertically arranged cell cells 110, and a plurality of electrically connected cell cells 110. The anode-side terminal 133 with the anode-side termination facing the external input / output terminals, the cathode-side terminal 134 with the cathode-side terminations of a plurality of electrically connected cells 110 facing the external input / output terminals, and the bus bar. Includes a protective cover 135 that protects 132 and the like.

As shown in FIGS. 2 and 4, the bus bar holder 131 integrally holds a plurality of bus bars 132. The bus bar holder 131 integrally holds the plurality of bus bars 132 in a matrix so as to face the electrode tabs 112 of each of the cell 110s of the laminated body 110S. The bus bar holder 131 is made of an insulating resin and is formed in a frame shape.

As shown in FIG. 4, the bus bar holder 131 is a pair of columns that stand up along the Z direction so as to be located on both sides of the first spacer 114 that supports the electrode tab 112 of the cell 110 in the longitudinal direction. Each unit 131a is provided. The pair of support columns 131a are fitted to the side surfaces of the first spacer 114. The pair of support columns 131a are L-shaped when visually recognized along the Z direction, and are formed in a plate shape extending along the Z direction. The bus bar holder 131 is provided with a pair of auxiliary strut portions 131b standing up in the Z direction apart from each other so as to be located near the center in the longitudinal direction of the first spacer 114. The pair of auxiliary strut portions 131b are formed in a plate shape extending along the Z direction.

As shown in FIG. 4, the bus bar holder 131 includes an insulating portion 131c that projects between adjacent bus bars 132 in the Z direction. The insulating portion 131c is formed in a plate shape extending along the Y direction. Each insulating portion 131c is provided horizontally between the auxiliary strut portion 131b and the auxiliary strut portion 131b. The insulating portion 131c prevents electric discharge by insulating between adjacent bus bars 132 along the Z direction.

The bus bar holder 131 may be configured by joining the column portion 131a, the auxiliary column portion 131b, and the insulating portion 131c, which are independently formed, to each other, or the column portion 131a, the auxiliary strut portion 131b, and the insulating portion 131c are integrally formed. It may be formed by molding.

As shown in FIGS. 3A, 3B, 4 and 5, the bus bar 132 electrically connects the electrode tabs 112 of the vertically arranged cell cells 110. The bus bar 132 electrically connects the anode side electrode tab 112A of one cell 110 and the cathode side electrode tab 112K of the other cell 110. As shown in FIG. 5, the bus bar 132 electrically has, for example, three anode side electrode tabs 112A arranged above and below the first cell subassi 110M and three cathode side electrode tabs 112K arranged above and below the second cell subassi 110N. Connect to.

That is, as shown in FIG. 5, the bus bar 132 connects, for example, the three anode-side electrode tabs 112A of the first cell sub-assi. .. Further, the bus bar 132 connects the three anode side electrode tabs 112A of the first cell subassi 110M and the three cathode side electrode tabs 112K of the second cell subassi 110N in series. The bus bar 132 is laser welded to the anode side electrode tab 112A of one cell 110 and the cathode side electrode tab 112K of the other cell 110.

As shown in FIGS. 3A and 4, the bus bar 132 is configured by joining the anode side bus bar 132A and the cathode side bus bar 132K. The anode-side bus bar 132A and the cathode-side bus bar 132K have the same shape and are each formed in an L shape. As shown in FIGS. 3A and 4, the bus bar 132 is integrated by a joint portion 132c formed by joining the refracted end of the anode side bus bar 132A and the refracted end of the cathode side bus bar 132K. As shown in FIG. 4, the anode-side bus bar 132A and the cathode-side bus bar 132K constituting the bus bar 132 are provided with side portions 132d to be joined to the bus bar holder 131 at both ends along the Y direction.

The anode-side bus bar 132A is made of aluminum, like the anode-side electrode tab 112A of the cell 110. The cathode side bus bar 132K is made of copper, like the cathode side electrode tab 112K of the cell 110. The anode-side bus bar 132A and the cathode-side bus bar 132K, which are made of different metals, are bonded to each other by ultrasonic bonding to form a bonding portion 132c.

Of the bus bars 132 arranged in a matrix, the bus bar 132 located at the upper right in the figure of FIG. 4 corresponds to the termination on the anode side of 21 single batteries 110 (3 parallel 7 series), and only from the anode side bus bar 132A. It is configured. The anode-side bus bar 132A is laser-bonded to the anode-side electrode tabs 112A of the top three single-cell batteries 110 among the stacked single-cell batteries 110.

Of the bus bars 132 arranged in a matrix, the bus bar 132 located at the lower left in the figure of FIG. 4 corresponds to the end of the cathode side of 21 single batteries 110 (3 parallel 7 series), and only from the cathode side bus bar 132K. It is configured. The cathode-side bus bar 132K is laser-bonded to the cathode-side electrode tabs 112K of the three lowermost single-cell batteries 110 among the stacked single-cell batteries 110.

As shown in FIGS. 1 and 2, the anode-side terminal 133 directs the anode-side terminations of the plurality of electrically connected cells 110 to the external input / output terminals. As shown in FIG. 2, the anode-side terminal 133 is joined to the anode-side bus bar 132A located at the upper right in the figure among the bus bars 132 arranged in a matrix. The anode-side terminal 133 is made of a conductive metal formed in a plate shape with both ends refracted.

As shown in FIGS. 1 and 2, the cathode-side terminal 134 has the cathode-side terminations of the plurality of electrically connected cell cells 110 facing the external input / output terminals. As shown in FIG. 2, the cathode side terminal 134 is joined to the cathode side bus bar 132K located at the lower left in the figure among the bus bars 132 arranged in a matrix. The cathode side terminal 134 has a shape similar to that of the anode side terminal 133, and the top and bottom are inverted.

As shown in FIGS. 1 and 2, the protective cover 135 protects the bus bar 132 and the like. That is, the protective cover 135 integrally covers the plurality of bus bars 132 to prevent each bus bar 132 from coming into contact with other members or the like to cause an electrical short circuit. As shown in FIG. 2, the protective cover 135 is made of insulating plastics in which one end 135b and the other end 135c of the side surface 135a standing up in the Z direction are bent in the X direction like a claw. ..

The protective cover 135 covers each bus bar 132 with the side surface 135a, and fixes the bus bar holder 131 by sandwiching it from above and below with one end 135b and the other end 135c. The protective cover 135 has a first opening 135d made of a rectangular hole for the anode side terminal 133 to face the outside and a second opening 135e made of a rectangular hole for the cathode side terminal 134 facing the outside. Be prepared for.

The effects of the embodiments described above will be described.

The first spacer 114 is used for the cell 110 including the battery body 110H including the power generation element 111 and formed flat, and the electrode tab 112 derived from the battery body 110H. The first spacer 114 has a boss 114r, a first recess 114s, and a first opening 114v. The boss 114r is formed in a convex shape and is inserted into a hole 112e or a notch provided in the electrode tab 112 to guide the electrode tab 112. The first recess 114s is formed in a concave shape and is separated from the electrode tab 112 around the root of the boss 114r. The first opening 114v communicates a part of the first recess 114s to the side surface side.

The assembled battery 100 includes a cell 110, a spacer (first spacer 114), and a bus bar 132. The cell 110 includes a flat battery body 110H including a power generation element 111, and an electrode tab 112 (anode side electrode tab 112A and cathode side electrode tab 112K) derived from the battery body 110H. The first spacer 114 has a convex protrusion (boss 114r) formed in a hole 112e provided in the electrode tab 112 or a notch to guide the electrode tab 112, and the electrode tab 112 around the base of the boss 114r. It is provided with a recess (first recess 114s) formed in a concave shape so as to be separated from the surface, and an opening (first opening 114v) for communicating a part of the first recess 114s to the side surface side. The bus bar 132 electrically connects the electrode tabs 112 of different cell units 110 to each other.

According to the first spacer 114, as shown in FIG. 12, a part of the first recess 114s is made to face the side surface (contact surface 114h) by the first opening 114v. That is, the assembled battery 100 provided with the first spacer 114 and the first spacer 114 can discharge water droplets and a water film generated by dew condensation from the first recess 114s to the outside through the first opening 114v. .. The water droplet or the water film is discharged to the outside as a liquid through the first opening 114v, or is vaporized and discharged to the outside. Therefore, the assembled battery 100 provided with the first spacer 114 and the first spacer 114 can suppress electric leakage due to dew condensation.

Here, as shown in FIG. 9, the first spacer 114 is formed so that the first recessed portion 114s is dug deeper than the periphery of the root of the boss 114r, but it is not necessary to make a large depression. Therefore, the first spacer 114 can be easily manufactured without impairing moldability (particularly, the change in external dimensions during cooling during processing is extremely small).

Further, in the assembled battery 100, as shown in FIG. 3B, the upper surface 114a of the first spacer 114 and the lower surface 114d of the other first spacer 114 are brought into contact with each other so that the plurality of first spacers 114 are densely packed. Can be laminated and configured. In particular, in the assembled battery 100, water droplets and a water film accumulated in the first spacer 114 adhere to, for example, the metal hollow spacer 116 inserted in the first spacer 114 locate hole 114g to form a water column, which is connected vertically. It is possible to prevent the assembled battery 100 from being transmitted to the ground in the vehicle arranged through the hollow spacer 116. Therefore, the assembled battery 100 can prevent the insulation resistance from decreasing. In this way, the assembled battery 100 can suppress electric leakage through, for example, the hollow spacer 116 having high conductivity.

It is preferable that the first spacer 114 further has contact portions (first contact portion 114i and second contact portion 114j) that protrude in the same direction as the boss 114r and come into contact with the cell 110.

According to the first spacer 114, as shown in FIG. 12, the height around the first contact portion 114i and the second contact portion 114j is higher than that of the first contact portion 114i and the second contact portion 114j. An opening (second opening 114W) can be formed from the second recess 114t, which has a relatively low height, toward the side surface (contact surface 114h). That is, the water droplets and the water film generated by the dew condensation can be discharged from the second recess 114t to the outside through the second opening 114W facing the side surface (contact surface 114h). Therefore, the first spacer 114 can further suppress electric leakage caused by dew condensation.

Further, as shown in FIG. 9, the first spacer 114 is formed so that the second recessed portion 114t is dug deeper than the first contact portion 114i and the second contact portion 114j. The outer shape of the first spacer 114 itself does not need to be expanded in the horizontal direction or the vertical direction. As described above, the first spacer 114 can supply water without providing an extra space (surplus space for securing the creepage distance and the space distance) which may be disadvantageous for the improvement of the volume density by the second recess 114t. It can be discharged to the outside to suppress the generation of conduction paths due to water droplets and water film due to dew condensation.

Further, as shown in FIG. 9, the first spacer 114 is formed so that the second recessed portion 114t is dug deeper than the first contact portion 114i and the second contact portion 114j, but is greatly recessed. There is no need. Therefore, the first spacer 114 can be easily manufactured without impairing moldability (particularly, the change in external dimensions during cooling during processing is extremely small).

It is preferable that the first contact portion 114i comes into contact with the one end portion 112g, the central portion 112f, and the other end portion 112h along the width direction of the electrode tab 112.

According to the first spacer 114, when the boss 114r is crimped and fixed to the portion of the hole 112e provided in, for example, the central portion 112f of the electrode tab 112, the crimped portion is distorted and the electrode tab 112 It is possible to prevent both ends (one end 112g and the other end 112h) from being deformed so as to float from the first spacer 114. That is, since the first contact portion 114i partially supports the central portion 112f, the one end portion 112g, and the other end portion 112h of the electrode tab 112, the distortion of the electrode tab 112 due to the crimping becomes the first. The strain of the electrode tab 112 can be retained at the central portion 112f without propagating to both ends (one end portion 112g and the other end portion 112h) of the electrode tab 112 via the first contact portion 114i of the spacer 114. .. Therefore, when the electrode tab 112 is processed by laser irradiation, it is possible to prevent the laser from not being properly irradiated due to the misalignment of the electrode tab 112 (so-called blank laser striking). Further, the first spacer 114 allows water droplets and water film generated by dew condensation to be collected from the gap of the first contact portion 114i (the gap located between the central portion 112f of the electrode tab 112 and the one end portion 112g, and the electrode tab 112. It can be discharged to the outside through a gap (a gap located between the central portion 112f and the other end portion 112h). Therefore, according to the first spacer 114, the distortion of the electrode tab 112 due to the crimping of the boss 114r is locally suppressed, the entire electrode tab 112 is prevented from being deformed, and the first spacer 114 and the electrode tab 112 are strengthened. Leakage caused by dew condensation can be suppressed while maintaining the temperature.

It is preferable that at least a part of the second contact portion 114j of the first spacer 114 is formed in an annular shape.

According to the first spacer 114, as shown in FIG. 7, water droplets and a water film generated by dew condensation are stored in a third recess 114u surrounded by a second contact portion 114j formed in an annular shape. , It can be vaporized from the gap between the cell 110 and the first spacer 114 and discharged to the outside. That is, the third recess 114u surrounded by the second contact portion 114j functions as a pocket for temporarily storing water. Therefore, according to the first spacer 114, it is possible to suppress electric leakage due to dew condensation.

In addition, the present invention can be modified in various ways based on the configurations described in the claims, and these are also within the scope of the present invention.

In the spacer (for example, the first spacer 114), the side surface facing a part of the recess (the first recess 114s and the second recess 114t) is the side surface (short direction) along the direction Y (short direction) of the cell 110. The side surface is not limited to the contact surface 114h), and may be a side surface along the direction X (longitudinal direction) of the cell 110.

100 sets of batteries,
110 cell,
110M 1st cell subassi,
110N 2nd cell subassi,
110S laminate,
110H battery body,
111 power generation element,
112 electrode tab,
112A Anode side electrode tab,
112K cathode side electrode tab,
112c base end,
112d tip,
112e hole,
112f central part,
112g one end,
112h other end,
113 Laminated film,
114 1st spacer,
114a top surface,
114b support surface,
114c connecting pin,
114d bottom surface,
114e Positioning Pin,
114f Positioning hole,
114g locate hole,
114h contact surface,
114i 1st contact part (contact part),
114j 2nd contact part (contact part),
114k pressing part,
114r boss (protrusion),
114s 1st depression (recess),
114t 2nd depression (recess),
114u 3rd depression (recess),
114v 1st opening (opening),
114W 2nd opening (opening),
115 Second spacer,
116 Hollow spacer,
120 pressurization unit,
121 Upper pressure plate,
122 Lower pressure plate,
123 side plate,
130 bus bar unit,
131 Bus Bar Holder,
132 Basba,
132A Anode side bus bar,
132K cathode side bus bar,
133 Anode side terminal,
134 Cathode side terminal,
135 protective cover,
Longitudinal direction of X cell 110,
The short side of the Y cell 110,
Z Stacking direction of the cell 110.

Claims (5)

A spacer used for a cell cell provided with a flat battery body including a power generation element and an electrode tab derived from the battery body.
A convexly formed protrusion that is inserted into a hole or notch provided in the electrode tab to guide the electrode tab,
A concave portion formed in a concave shape around the base of the protrusion so as to be separated from the electrode tab,
A spacer having an opening for communicating a part of the recess to the side surface side. The spacer according to claim 1, further comprising a contact portion that protrudes in the same direction as the protrusion portion and comes into contact with the cell. The spacer according to claim 2, wherein the abutting portion abuts on one end, a center, and the other end along the width direction of the electrode tab. The spacer according to claim 2 or 3, wherein the contact portion is formed at least in a ring shape. A cell having a flat battery body including a power generation element and an electrode tab derived from the battery body.
A convexly formed protrusion provided on the electrode tab and inserted into a hole or notch formed in a long shape from the base end portion to the tip end portion of the electrode tab to guide the electrode tab, and the protrusion portion. A spacer provided with a recess formed in a concave shape around the root so as to be separated from the electrode tab, and an opening for communicating a part of the recess to the side surface side in contact with the tip of the electrode tab. When,
Different said bus bar connecting the electrode tabs to each other of the single cells electrically, have a, said in the hole or condition of inserting the protruding portion of the spacer to the cutout of the electrode tab hole or the cutout one An assembled battery in which a portion is open and the opening portion of the hole or the notch communicates with the opening portion of the spacer .